JP4026075B2 - Information processing apparatus and method, and recording medium - Google Patents

Description

Technical field
The present invention relates to an information processing device and method, and a recording medium, and more particularly to an information processing device and method, and a recording medium that can communicate via radio waves.
Background art
Recently, cellular phones, PDAs (Personal Digital Assistants) and the like have rapidly spread. As a result, each user has more opportunities to exchange information among a plurality of these devices.
Conventionally, when such information exchange is performed, devices are connected to each other via a cradle or a cable, or infrared transmission / reception units face each other for transmission / reception.
However, the wired connection is not only complicated, but a connector suitable for each model must be prepared, which is inconvenient.
In addition, when using infrared rays, there is a problem that communication is interrupted if the user obstructs the infrared transmission path by inadvertently passing it.
Therefore, it has been proposed to perform wireless communication between a plurality of devices by a wireless LAN (Local Area Network), a proximity wireless LAN represented by Bluetooth (trademark), or the like.
However, for example, even when information is exchanged between a PDA held by the user and a device installed in front of the user, the distance that can be communicated without actually communicating I can't know if it is. As described above, when performing wireless communication, there is a problem that the user cannot know the communication distance that can be actually connected to the device whose information is to be exchanged.
Disclosure of the invention
The present invention has been made in view of such a situation, and when performing wireless communication, it is possible to know a communication distance that can be actually connected and to exchange information reliably. .
An information processing apparatus according to the present invention includes a communication unit that communicates with an electronic device via radio waves, an acquisition unit that acquires identification information of the electronic device, and an electronic device that is within a communication range of communication performed by the communication unit. A display control unit configured to control display of an image of the shape of the electronic device specified by the identification information acquired by the acquisition unit among the plurality of electronic devices based on the input level of the transmitted radio wave. And
The acquisition means acquires the identification information of the electronic device by any one of a communication method for transmitting / receiving information via electromagnetic waves or a Bluetooth communication method for identifying a communication partner by searching for devices in the weak power mode. And a communication means can be made to communicate with an electronic device based on identification information.
The display control means can control the display so that the image is displayed with transparency corresponding to the input level of the radio wave.
The display control means can control the display so that an image is displayed at a position corresponding to the input level of the radio wave.
The display control means can control the display so as to display an image having a size corresponding to the input level of the radio wave.
The display control means can control the display so as to display an image having a resolution corresponding to the input level of the radio wave.
The display control means can control the display so that the image is displayed in a color corresponding to the input level of the radio wave.
The display control means can control the display so as to display an image to which mosaic processing corresponding to the input level of radio waves is applied.
The information processing method according to the present invention includes a communication processing step for communicating with an electronic device via radio waves, an acquisition processing step for acquiring identification information of the electronic device, and a communication range of communication performed by the processing of the communication processing step. Display that controls the display of the image of the shape of the electronic device specified by the identification information acquired by the processing of the acquisition processing step among the plurality of electronic devices based on the input level of the radio wave transmitted from the existing electronic device And a control processing step.
The program recorded in the recording medium of the present invention includes a communication processing step for communicating with an electronic device via radio waves, an acquisition processing step for acquiring identification information of the electronic device, and a communication performed by processing of the communication processing step. The image of the shape of the electronic device identified by the identification information acquired by the processing of the acquisition processing step among the plurality of electronic devices based on the input level of the radio wave transmitted from the electronic device existing within the communication range of And a display control processing step for controlling display.
In the information processing apparatus and method of the present invention and the program recorded in the recording medium, communication with the electronic device is performed via radio waves, and identification information of the electronic device is acquired. Moreover, based on the input level of the radio wave transmitted from the electronic device existing within the communication range, the display of the image of the shape of the electronic device specified by the identification information among the plurality of electronic devices is controlled.
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 1 shows a configuration example of an information processing system to which the present invention is applied. In this configuration example, a personal computer 1 has an input display unit 2 and a main body 3 connected thereto. On the input display unit 2, predetermined information is displayed, and predetermined information can be input by operating a pen or the like (not shown) on the input display unit 2.
In addition, the input display unit 2 allows a user to exchange data between the mobile phone 11 and the personal computer 1 by placing the mobile phone 11 as necessary, for example. ing.
FIG. 2 shows a configuration example of the personal computer 1. A CPU (Central Processing Unit) 21 executes various processes according to a program stored in a ROM (Read Only Memory) 22 or a storage unit 26. A RAM (Random Access Memory) 23 appropriately stores programs executed by the CPU 21, data, and the like. The CPU 21, ROM 22, and RAM 23 are connected to each other via a bus 24. An input / output interface 25 is also connected to the bus 24. In addition to the input display unit 2, the input / output interface 25 is connected to a storage unit 26 constituted by a hard disk or the like, for example, a communication unit 27 that communicates with other devices via a telephone line.
The communication unit 28 is a so-called Bluetooth module. The communication unit 28 communicates with the communication unit 213 (see FIG. 6), which is a Bluetooth module provided in the mobile phone 11, for example.
Bluetooth is a wireless communication standard standardized by Bluetooth SIG (Special Interest Group), and uses other 2.4 GHz band (ISM (Industrial Science Medical) band) and other devices (with Bluetooth module). (Referred to as Bluetooth device as appropriate).
The network formed by Bluetooth is called a piconet or a scatternet in which a plurality of piconets are interconnected depending on the form, and has a role called a master and a slave. There is a Bluetooth device with Hereinafter, a Bluetooth device having a master role is simply referred to as a master, and a Bluetooth device having a slave role is simply referred to as a slave.
In order for a piconet to be formed and to transmit and receive various types of information, it is necessary that synchronization between the frequency axis and the time axis be established by all the Bluetooth devices in the piconet.
Here, the synchronization of the frequency axis and the synchronization of the time axis will be briefly described.
In Bluetooth, for example, a signal is transmitted from a master to a slave using a frequency width of 79 MHz. At this time, the master does not transmit information by simultaneously occupying the frequency width of 79 MHz. The transmission frequency is randomly changed (hopped) with a frequency width of 1 MHz and transmitted.
In addition, the slave on the receiving side synchronizes with the transmission frequency of the master that is randomly changed, and appropriately receives the information transmitted from the master by changing the reception frequency.
The frequency pattern changed by the master and the slave is called a frequency hopping pattern, and a state in which the frequency hopping pattern is shared between the master and the slave is a state in which frequency axis synchronization is established.
In Bluetooth, since a master and a plurality of slaves communicate with each other, a communication path (channel) between the master and each slave is time-division multiplexed in units of 625 μsec. This time interval in units of 625 μsec is called a time slot, and a state in which the time slot is shared is a state in which time axis synchronization is established.
All slaves calculate a frequency hopping pattern to establish frequency axis synchronization based on the master's Bluetooth address, and add an offset to the Bluetooth clock managed by itself based on the master's Bluetooth clock. Take time slot timing to establish time axis synchronization.
This Bluetooth address is represented by 48 bits unique to each Bluetooth device, and based on this, a frequency hopping pattern is uniquely calculated. The Bluetooth clock is managed by all the Bluetooth devices.
Therefore, before forming the piconet, various information including the Bluetooth address and the Bluetooth clock for establishing the synchronization of the frequency axis and the synchronization of the time axis are transmitted and received between the master and the slave.
Returning to FIG. 2, the input display unit 2 includes a transparent tablet 31 that detects the user's pen operation, and an LCD (Liquid Crystal Display) that is disposed below the tablet 31 and displays images such as characters and graphics. 32 is provided. The input display unit 2 is further provided with a reader / writer 33 that communicates with the RF tag 212 (FIG. 6) of the mobile phone 11.
A drive 29 is further connected to the input / output interface 25, and a magnetic disk 41, an optical disk 42, a magneto-optical disk 43, a semiconductor memory 44, or the like can be appropriately attached to the drive 29. . Programs read from the magnetic disk 41 to the semiconductor memory 44 are supplied from the drive 29 to the storage unit 26 via the input / output interface 25.
FIG. 3 is a block diagram illustrating a detailed configuration example of the reader / writer 33.
The IC 81 includes a CPU 91, an SPU (Signal Processing Unit) 92, an SCC (Serial Communication Controller) 93, and a memory 94, and the memory 94 includes a ROM 101 and a RAM 102. These CPU 91 to memory 94 are connected to each other via a bus 95.
The CPU 91 expands the control program stored in the ROM 101 in the RAM 102, and based on response data transmitted from the RF tag 212 of the mobile phone 11 described later and the control signal supplied from the CPU 21 in FIG. Perform various processes. For example, the CPU 91 generates a command to be transmitted to the RF tag 212, outputs it to the SPU 92 via the bus 95, and performs an authentication process for data transmitted from the RF tag 212.
Further, the CPU 91 performs processing such as notifying the communication unit 28 based on an instruction from the CPU 21 when the mobile phone 11 is disposed in the vicinity and a Bluetooth device name is notified by processing of each unit described later. Do.
When the response data from the RF tag 212 is supplied from the demodulator 84, the SPU 92 performs, for example, BPSK (Binary Phase Shift Keying) demodulation on the data and supplies the acquired data to the CPU 91. Further, when a command to be transmitted to the RF tag 212 is supplied via the bus 95, the SPU 92 performs modulation processing (primary modulation) on the command and outputs the acquired data to the modulation unit 82.
The SCC 93 supplies the data supplied from the CPU 21 to the CPU 91 via the bus 95, and outputs the data supplied from the CPU 91 via the bus 95 to the CPU 21.
The modulation unit 82 modulates a carrier wave having a predetermined frequency supplied from the oscillation circuit (OSC) 83 as ASK (Amplitude Shift Keying) as secondary modulation based on data supplied from the SPU 92, and generates a modulated wave. Are output from the antenna 85 as electromagnetic waves. On the other hand, the demodulator 84 demodulates the modulated wave (ASK modulated wave) acquired via the antenna 85 and outputs the demodulated data to the SPU 92.
The antenna 85 radiates a predetermined electromagnetic wave and detects whether or not the RF tag 212 (the mobile phone 11) is disposed in the vicinity based on a change in load with respect to the predetermined electromagnetic wave. When the RF tag 212 is disposed in the vicinity, the antenna 85 transmits and receives various data to and from the RF tag 212.
FIG. 4 is a block diagram illustrating a detailed configuration example of the communication unit 28 that is a Bluetooth module.
The CPU 121 develops a control program stored in the ROM 122 in the RAM 123 and controls the overall operation of the communication unit 28. The CPU 121 to RAM 123 are connected to each other via a bus 125, and a flash memory 124 is connected to the bus 125.
The flash memory 124 stores, for example, a Bluetooth device name that is set for each Bluetooth device and can be changed by the user according to preference, a Bluetooth address unique to each Bluetooth device, and the like. Has been.
The Bluetooth address is a 48-bit identifier and is unique (unique) to each Bluetooth device, and thus is used for various processes related to management of the Bluetooth device.
For example, as described above, in order to establish intra-piconet synchronization, all slaves must obtain information about the master's frequency hopping pattern, which is based on the master's Bluetooth address. It is calculated by the slave.
More specifically, the Bluetooth address has a lower 24 bits as LAP (Low Address Part), the next 8 bits as UAP (Upper Address Part), and the remaining 16 bits as NAP (Non-significant Address Part). The frequency hopping pattern is calculated using 28 bits consisting of 24 bits of the entire LAP and the lower 4 bits of the UAP.
Each slave has a frequency hopping pattern based on the 28-bit portion of the master's Bluetooth address obtained at the time of the call to establish intra-piconet synchronization and the Bluetooth clock notified from the master as well. Can be calculated.
The frequency hopping pattern includes an inquiry frequency hopping pattern used at the time of inquiry, a calling frequency hopping pattern used at the time of calling, and communication between the slave and the master after intra-piconet synchronization is established. A channel frequency hopping pattern that is sometimes used is defined. In the following, when it is not necessary to individually distinguish the three frequency hopping patterns, they are simply referred to as frequency hopping patterns.
The flash memory 124 also stores a link key for authenticating the Bluetooth device of the communication partner and encrypting data to be transmitted after synchronization in the piconet is established, and requires a stored link key, etc. To the CPU 121 accordingly.
The input / output interface 126 manages input / output of data supplied from the CPU 21 of FIG. 2 and data supplied from the baseband control unit 127 based on an instruction from the CPU 121.
The baseband control unit 127 supplies the data supplied from the input / output interface 126 to the GFSK (Gaussian Frequency Shift Keying) modulation unit 141 and transmits the data from the GFSK demodulation unit 147 to transmit the data to the mobile phone 11. When this occurs, it is output to the bus 125 or the input / output interface 126.
The GFSK modulation unit 141 limits the high frequency component of the data supplied from the baseband control unit 127 by a filter, performs frequency modulation as primary modulation, and outputs the acquired data to the spectrum spreading unit 142.
The spread spectrum unit 142 is obtained as described above, switching the carrier frequency based on the frequency hopping pattern notified from the hopping synthesizer unit 145, and applying the spread spectrum to the supplied data. The signal is output to the communication control unit 143. In Bluetooth, the spread spectrum unit 142 transmits data by hopping the frequency every 625 μsec.
The communication control unit 143 transmits a spectrum-spread signal from the antenna 144 using the 2.4 GHz band. In addition, the communication control unit 143 outputs the reception signal from the antenna 144 to the inverse spectrum spreading unit 146.
The inverse spread spectrum unit 146 hops the reception frequency based on the frequency hopping pattern notified from the hopping synthesizer unit 145 and acquires, for example, a signal from the mobile phone 11. The inverse spectrum spread unit 146 performs inverse spectrum spread on the acquired signal and outputs a signal obtained after reproducing the signal from the mobile phone 11 to the GFSK demodulator 147. The GFSK demodulation unit 147 performs GFSK demodulation on the signal supplied from the inverse spectrum spreading unit 146 and outputs the obtained data to the baseband control unit 127.
FIG. 5 is a block diagram illustrating a configuration of a program executed by the personal computer 1. The operating system (Operation System (basic program software)) 161 is, for example, Microsoft Windows (registered trademark) Me (Windows (R) Me), Windows (registered trademark) 2000 (Windows (R) 2000), or Apple. It controls the basic operation of a computer represented by Mac OS (trademark) of Computer Corporation.
The reader / writer control program 162 controls the reader / writer 33 to detect the presence of a terminal having a built-in RF tag 212 disposed in the vicinity of the personal computer 1, and to perform various kinds of operations via the terminal and electromagnetic waves. Send and receive information.
The Bluetooth control program 163 controls the communication unit 28 to detect, for example, a Bluetooth device existing in the vicinity and establish synchronization for communicating with the Bluetooth device.
The display control program 164 controls the display of images such as characters or figures on the LCD 32 of the input display unit 2.
The e-mail program 165 transmits an e-mail to another device such as a server or receives an e-mail from another device via the communication unit 27.
FIG. 6 illustrates a configuration example of the mobile phone 11. Since the CPU 201 through the input / output interface 205 have basically the same functions as the CPU 21 through the input / output interface 25 of the personal computer 1 shown in FIG.
In the mobile phone 11, an input unit 206 composed of various buttons and switches is connected to the input / output interface 205, and an LCD 207 for displaying predetermined information is connected. The input / output interface 205 is further connected to a storage unit 208 configured by a semiconductor memory or the like and a communication unit 209 that performs communication via a telephone line.
The microphone 210 captures the user's voice, and the speaker 211 outputs the voice to the user. The RF tag 212 has an IC inside, communicates with the reader / writer 33 of the personal computer 1, and transmits the Bluetooth device name and the like of the mobile phone 11 stored therein to the reader / writer 33. The RF tag 212 has a function of storing data supplied from the reader / writer 33 in a built-in memory.
The communication unit 213 is a Bluetooth module. For example, the communication unit 213 forms a piconet with the communication unit 28 of the personal computer 1, and transmits and receives various data based on instructions from the CPU 201.
Note that the configuration of the communication unit 213 is the same as that shown in FIG.
FIG. 7 is a block diagram illustrating a detailed configuration example of the RF tag 212.
The RF tag 212 includes, for example, an antenna 240 shown in the figure and an IC in which components other than the antenna 240 are stored in one chip. For example, Felica (registered trademark) is provided as a device that provides basically the same function as the RF tag 212.
The CPU 231 expands the control program stored in the ROM 232 in the RAM 233 and controls the overall operation of the RF tag 212. For example, when the electromagnetic wave radiated from the reader / writer 33 is received by the antenna 240, the CPU 231 notifies the reader / writer 33 of the identification information set in the RF tag 212 accordingly.
This identification information can be changed freely. For example, the identification information is the same as the Bluetooth device name set in the communication unit 213 (mobile phone 11) which is a Bluetooth module, or includes the Bluetooth device name. .
In FIG. 7, a data transmission unit 237, a BPSK modulation unit 238, a BPSK demodulation unit 241, and a data reception unit 242 correspond to the SPU 92 of the reader / writer 33 shown in FIG. 3, and correspond to the ASK modulation unit 252 and the ASK demodulation. The unit 253 corresponds to the modulation unit 82 and the demodulation unit 84, and the basic processing is the same as that described above, and thus detailed description thereof is omitted.
For example, when the mobile phone 11 is disposed in the vicinity of the personal computer 1, the identification information is read from the EEPROM 234 and output to the data transmission unit 237. The identification information supplied to the data transmission unit 237 is BPSK modulated as primary modulation in the BPSK modulation unit 238 and then output to the ASK modulation unit 252.
In response to the data supplied from the BPSK modulation unit 238, the ASK modulation unit 252 turns on / off a predetermined switching element, fluctuates the load of the antenna 240, and the reader / writer 33 received by the antenna 240 The modulated component is ASK-modulated to transmit the modulated component to the reader / writer 33 (the terminal voltage of the antenna 85 of the reader / writer 33 is varied).
In addition, the RF tag 212 not only notifies the personal computer 1 of the identification information, but also performs various processes such as an authentication process with the reader / writer 33 and an encryption process of data to be transmitted. .
FIG. 8 is a diagram illustrating an example of functional blocks of the mobile phone 11.
The host program 271 provides basic functions of the mobile phone 11, and provides, for example, a call function and an e-mail transmission / reception function. The RF tag control program 272 controls the operation of the RF tag 212 and performs various processes based on instructions from the host program 271.
For example, when the mobile phone 11 is placed in the vicinity of the personal computer 1, the RF tag control program 272 provides the set identification information to the reader / writer 33 or receives electromagnetic waves from the reader / writer 33. In response, the communication unit 213 (Bluetooth control program 273), which is a Bluetooth module, is activated.
The Bluetooth control program 273 controls the operation of the communication unit 213 and realizes communication with other Bluetooth devices.
Next, operations of the personal computer 1 and the mobile phone 11 will be described with reference to the flowcharts of FIGS. 9 and 10. When the user wants to perform processing such as data exchange between the mobile phone 11 and the personal computer 1, the user moves the mobile phone 11 to a predetermined position of the input display unit 2 (a reader indicated by a dotted line in FIG. 1). It is placed at the position where the writer 33 is disposed.
The reader / writer 33 periodically transmits an electromagnetic wave with a sufficiently short period. When the mobile phone 11 is placed on the input display unit 2 (on the reader / writer 33), the reader / writer 33 and the mobile phone 11 are placed. Due to the electromagnetic coupling of the RF tag 212, the equivalent impedance of the antenna built in the reader / writer 33 changes. Based on the control of the reader / writer control program 162, the reader / writer 33 determines whether or not the mobile phone 11 is placed by monitoring the change of the impedance in step S1 of FIG. Wait until
When the mobile phone 11 is placed on the reader / writer 33, the reader / writer 33 corresponds to the Bluetooth device corresponding to the communication unit 213 in step S 2 under the control of the reader / writer control program 162. Request to send name.
Based on this request, a Bluetooth device name is transmitted from the mobile phone 11 as will be described later. Therefore, in step S3, the reader / writer 33 receives from the mobile phone 11 under the control of the reader / writer control program 162. The process waits until a Bluetooth device name is received. When the Bluetooth device name is received, the process proceeds to step S4, where the received Bluetooth device name of the mobile phone 11 is supplied to the CPU 21. Under the control of the reader / writer control program 162, the CPU 21 supplies the device name to the RAM 23 and stores it.
Next, in step S5, the CPU 21 that executes the Bluetooth control program 163 controls the communication unit 28 to connect to the Bluetooth device corresponding to the device name of the mobile phone 11 stored in step S4, and is necessary for data transfer. Have a link set up.
Specifically, when the communication unit 213 of the mobile phone 11 is in the standby phase, the CPU 21 causes the communication unit 28 to execute an inquiry and call in the synchronization establishment phase to establish synchronization with the communication unit 213.
When synchronization between the communication unit 28 and the communication unit 213 is established, the communication unit 28 of the personal computer 1 and the communication unit 213 of the mobile phone 11 shift to the communication connection phase.
The CPU 21 establishes a communication link to the Bluetooth device corresponding to the device name of the mobile phone 11 among the Bluetooth devices in the piconet in which the communication unit 28 is synchronized with the frequency axis and the time axis. Is transmitted, and an ACL (Asynchronous Connection-Less) link necessary for processing in the next step is set.
Thereafter, in step S6, the personal computer 1 executes a predetermined process with the mobile phone 11 via the network. A specific example of this process will be described later.
On the other hand, the RF tag 212 of the cellular phone 11 determines whether or not the electromagnetic wave is received from the reader / writer 33 of the personal computer 1 in step S11 of FIG. 10 (mounted on the input display unit 2 of the personal computer 1). To determine whether it has been placed). When it is determined that the mobile phone 11 is placed on the input display unit 2, the process proceeds to step S12, and the RF tag 212 is requested to transmit a Bluetooth device name under the control of the RF tag control program 272. Wait until As described above, since the reader / writer 33 of the personal computer 1 requests the mobile phone 11 to transmit the Bluetooth device name in step S2, if it is determined that the transmission request is received, the step is performed. In step S 13, the RF tag 212 reads the Bluetooth device name stored in the internal memory and transmits it to the reader / writer 33 under the control of the RF tag control program 272.
The Bluetooth device name can also be stored in the ROM 202 or the storage unit 208. In this case, the device name read from them by the CPU 201 is transmitted from the RF tag 212.
In step S14, the CPU 201 of the mobile phone 11 that executes the Bluetooth control program 273 waits until the communication unit 28 and the communication unit 213 of the personal computer 1 are connected via Bluetooth communication (in this case, communication). Wait until the connection phase connection is reached).
When the communication unit 213 determines in step S14 that the communication unit 213 and the communication unit 28 of the personal computer 1 are connected via Bluetooth communication based on the control of the Bluetooth control program 273, the process proceeds to step S15. Since the communication unit 28 of the personal computer 1 transmits a control packet for setting a communication link in step S5, the control packet is received and a communication link is set between the personal computer 1 and the personal computer 1.
Thereafter, the process proceeds to step S16, and the mobile phone 11 executes a predetermined process with the personal computer 1 via the network. This process corresponds to the process in step S6 of FIG.
In the above example, the Bluetooth device name of the mobile phone 11 is transmitted and received as the identification information, but an identification number other than the Bluetooth device name of the mobile phone 11 is transmitted from the mobile phone 11 to the personal computer 1. On the personal computer 1 side, the Bluetooth device name of the mobile phone 11 as an address on the network may be searched based on the identification number.
11 and 12 show the operations of the personal computer 1 and the mobile phone 11 in this case.
The processing from step S51 to step S56 of the mobile phone 11 in FIG. 12 is basically the same as the processing from step S11 to step S16 in FIG. 10, requested from the personal computer 1 in step S52, and in step S53. The data to be transmitted is not a device name but an identification number, which is different from the case in FIG. 10, and other processes are the same as those in FIG.
Similarly, the processing in steps S31 to S37 of the personal computer 1 in FIG. 11 is basically the same as the processing in steps S1 to S6 shown in FIG. However, in the processing of FIG. 11, the Bluetooth device name is not directly transmitted from the mobile phone 11, but an identification number is transmitted. Therefore, in step S <b> 34, the CPU 21 of the personal computer 1 In step S35, a process for searching for the Bluetooth device name from the identification number of the mobile phone 11 is executed. For this search, a correspondence table between the identification number of the mobile phone 11 and the Bluetooth device name may be stored in the storage unit 26 in advance, or from the communication unit 27, for example, via the Internet or the like. The Bluetooth device name corresponding to the identification number of the mobile phone 11 may be searched through the server.
The processing after the Bluetooth device name of the mobile phone 11 is searched is the same processing as shown in FIG.
Next, an example of processing executed in step S6 in FIG. 9 (step S37 in FIG. 11) and step S16 in FIG. 10 (step S56 in FIG. 12) will be further described.
FIG. 13 shows an example in which the cellular phone 11 is placed on the input display unit 2 so that the content of the mail registered in the cellular phone 11 is enlarged and displayed on the LCD 32 of the input display unit 2. Yes.
Next, processing of the cellular phone 11 and the personal computer 1 in this case will be described with reference to the flowcharts of FIGS. 14 and 15.
In step S71 of FIG. 14, the CPU 201 of the mobile phone 11 reads the sender and subject (subject) of the mail received so far, stored in the RAM 203, and in step S72, reads them to the communication unit 213. The sender and subject of the received mail are transmitted to the personal computer 1. In other words, at this time, the CPU 201 controls the communication unit 213 to transmit to the personal computer 1 via Bluetooth communication.
As will be described later, the sender and subject of the sent mail are displayed on the LCD 32 of the personal computer 1, and when the user selects a predetermined one from the display, the selection is transmitted to the mobile phone 11. come.
Therefore, in step S73, the CPU 201 stands by until notified that the mail has been selected. When notified that the mail has been selected, the CPU 201 proceeds to step S74 and reads the content of the selected mail from the RAM 203. Then, the data is transmitted from the communication unit 213 to the personal computer 1.
Corresponding to the processing of the cellular phone 11, the personal computer 1 executes the processing shown in the flowchart of FIG.
First, in step S <b> 81, the CPU 21 receives a mail sender and a subject when they are transmitted from the mobile phone 11. That is, when the communication unit 28 receives a mail sender and subject from the communication unit 213 of the mobile phone 11 via Bluetooth communication, the communication unit 28 receives them and supplies them to the RAM 23 for storage. In step S82, the CPU 21 reads the sender and the subject stored in the RAM 23, outputs them to the LCD 32, and displays them. Thereby, for example, as shown in FIG. 13, the sender and subject of the mail transmitted from the mobile phone 11 are displayed in the window 301.
A user selects a mail by designating the sender or subject of one mail in the window 301 by operating the pen while looking at this display. Therefore, in step S83, the CPU 21 stands by until a mail is selected. When a mail is selected, the CPU 21 proceeds to step S84 and notifies the mobile phone 11 of the selected mail. That is, at this time, the CPU 21 controls the communication unit 28 to notify the mobile phone 11 of which mail is designated (selected) by the user via Bluetooth communication.
When the selected mail is notified, the content of the selected mail is transmitted from the mobile phone 11 as described above. Therefore, in step S85, the communication unit 28 determines the mail sent from the mobile phone 11. Receive content. The contents of this mail are once supplied to the RAM 23 and stored. In step S86, the CPU 21 reads the content of the mail stored in the RAM 23, and the right side of the position where the mobile phone 11 is placed on the LCD 32 or the position designated by the user with the pen (these positions are the tablet 31). Are detected and output and displayed. In this way, for example, as shown in FIG. 13, the content of the selected mail is displayed in the window 302. In the example of FIG. 13, the content of the second mail in the window 301 (the mail whose sender is BBB and the subject is bb) is displayed as “Today. Yes.
It is theoretically possible to exchange mail data by communication between the RF tag 212 and the reader / writer 33. However, since the transmission capacity of this communication is small, in the present invention, this communication is used only for transmitting identification information.
Next, the display which shows the state of communication in the information processing system which concerns on this invention is demonstrated.
FIGS. 16 to 18 are diagrams illustrating a first example of a display indicating a communication state in the information processing system according to the present invention. As shown in FIG. 16, when the mobile phone 11 is located in the vicinity of the personal computer 1 and the electric field strength formed by the mobile phone 11 is sufficiently large at the position of the personal computer 1, The input level of the transmitted radio wave is sufficiently high.
When the input level of the radio wave transmitted from the mobile phone 11 is equal to the maximum input, the personal computer 1 sets the transparency to 0 and the mobile phone to the LCD 32 of the input display unit 2 so as not to transmit the background image at all. 11 is displayed.
As shown in FIG. 17, the mobile phone 11 is located in the middle of the communication range of the personal computer 1 (for example, the distance between the personal computer 1 and the mobile phone 11 is about 5 m) and transmitted from the mobile phone 11 of the communication unit 28. When the input level of the received radio wave is about half of the maximum input, the personal computer 1 displays the image 321 corresponding to the mobile phone 11 on the LCD 32 of the input display unit 2 with the transparency being 50%, for example.
That is, for example, the personal computer 1 adds ½ of the pixel value of a predetermined pixel of the original image of the image 321 and ½ of the pixel value of the corresponding pixel of the background image to make it translucent. The pixel value of is calculated. The personal computer 1 displays a translucent image 321 corresponding to the mobile phone 11 on the LCD 32 of the input display unit 2 based on the calculated pixel value.
As shown in FIG. 18, the mobile phone 11 is located at the end of the communication range of the personal computer 1 (for example, the distance between the personal computer 1 and the mobile phone 11 is about 10 m). When the input level of the transmitted radio wave is about the same as the reception sensitivity, the personal computer 1 causes the LCD 32 of the input display unit 2 to display an image 321 corresponding to the mobile phone 11 with a transparency of 90%, for example.
That is, for example, the personal computer 1 adds 90% of the pixel value of the background image and 10% of the pixel value of the original image 321 to calculate a pixel value corresponding to the image 321. The personal computer 1 displays a substantially transparent image 321 corresponding to the mobile phone 11 on the LCD 32 of the input display unit 2 based on the calculated pixel value.
FIG. 19 is a flowchart for explaining processing for displaying a radio wave state by the personal computer 1.
In step S <b> 101, the CPU 121 of the communication unit 28 of the personal computer 1 acquires the input level of the radio wave received from the mobile phone 11 from the RF unit 128 via the bus 125. The CPU 121 supplies data indicating the input level to the CPU 21 via the input / output interface 126, the input / output interface 25, and the like.
In step S102, the CPU 21 of the personal computer 1 that executes the display control program 164 calculates the transparency corresponding to the input level based on the data indicating the radio wave input level. For example, the CPU 21 calculates transparency by dividing the acquired data indicating the input level by a predetermined constant.
Note that the CPU 21 may obtain the transparency by comparing the data indicating the input level with one or more threshold values stored in advance. Alternatively, the CPU 21 may obtain the transparency based on the correspondence table between the input level and the transparency stored in advance in the storage unit 26.
In step S103, the CPU 21 executing the display control program 164 designates the transparency calculated in the process of step S102, causes the LCD 32 of the input display unit 2 to display an image of the communication partner device, and returns to step S101. Repeat the display process. For example, when the communication partner is the mobile phone 11, the CPU 21 designates the transparency calculated in the process of step S <b> 102 and causes the LCD 32 of the input display unit 2 to display an image 321 corresponding to the mobile phone 11.
As described above, the personal computer 1 can display an image of the communication partner whose transparency is changed in accordance with the radio wave state on the input display unit 2. In this way, the user can quickly know the radio wave state, that is, the communication state.
If the user determines the position of the mobile phone 11 so that an image with lower transparency is displayed on the input display unit 2, the personal computer 1 and the mobile phone 11 can exchange information more reliably.
20 to 22 are diagrams for explaining a second example of display indicating the state of communication in the information processing system according to the present invention. As shown in FIG. 20, when the mobile phone 11 is located in the vicinity of the personal computer 1 and the input level of the radio wave transmitted from the mobile phone 11 is equal to the maximum input, the personal computer 1 An image 341 corresponding to the mobile phone 11 is displayed in the center of the LCD 32.
As shown in FIG. 21, when the mobile phone 11 is located in the middle of the communication range of the personal computer 1 and the input level of the radio wave transmitted from the mobile phone 11 of the communication unit 28 is about half of the maximum input, For example, the computer 1 connects the mobile phone 11 to the LCD 32 of the input display unit 2 at a position on the diagonal line of the display surface of the LCD 32 and the distance to the center of the LCD 32 and the distance to the corner of the LCD 32 are the same. A corresponding image 341 is displayed.
As shown in FIG. 22, when the mobile phone 11 is located at the end of the communication range of the personal computer 1 and the input level of the radio wave transmitted from the mobile phone 11 of the communication unit 28 is about the same as the reception sensitivity, The personal computer 1 displays an image 341 corresponding to the mobile phone 11 on the corner of the LCD 32 of the input display unit 2.
FIG. 23 is a flowchart for explaining another process of displaying the radio wave state by the personal computer 1.
In step S <b> 121, the CPU 121 of the communication unit 28 of the personal computer 1 acquires the input level of the radio wave received from the mobile phone 11 from the RF unit 128 via the bus 125. The CPU 121 supplies data indicating the input level to the CPU 21 via the input / output interface 126, the input / output interface 25, and the like.
In step S122, the CPU 21 of the personal computer 1 that executes the display control program 164 calculates the display position based on the data indicating the input level of the radio wave. For example, when the radio wave input level is larger, the CPU 21 calculates the coordinates on the diagonal line of the display surface of the LCD 32 and closer to the center of the LCD 32. When the radio wave input level is smaller, the CPU 21 calculates the display surface of the LCD 32. The coordinates of a position closer to the corner of the LCD 32 are calculated.
In step S123, the CPU 21 executing the display control program 164 designates the display position corresponding to the input level calculated in the process of step S122, and displays the image of the communication partner device on the LCD 32 of the input display unit 2. Display, return to step S121, and repeat the display process. For example, when the communication partner is the mobile phone 11, the CPU 21 designates the display position calculated in the process of step S 122 and causes the LCD 32 of the input display unit 2 to display an image 341 corresponding to the mobile phone 11.
Thus, the personal computer 1 can display the image of the communication partner whose position has been changed on the input display unit 2 in accordance with the radio wave state. In this way, the user can quickly know the radio wave state, that is, the communication state.
If the user determines the position of the mobile phone 11 so that the image is displayed near the center of the input display unit 2, the personal computer 1 and the mobile phone 11 can exchange information more reliably.
Note that the personal computer 1 may display the input display unit 2 by changing the size of the image of the communication partner in accordance with the radio wave state. For example, when the input level of the radio wave transmitted from the mobile phone 11 is higher, the personal computer 1 displays a larger image of the communication partner on the input display unit 2, and the input level of the radio wave transmitted from the mobile phone 11 is higher. When it is smaller, the smaller image of the communication partner is displayed on the input display unit 2.
Further, the personal computer 1 may apply the mosaic process corresponding to the radio wave state to the image of the communication partner, and display the image to which the mosaic process is applied on the input display unit 2. For example, when the input level of the radio wave transmitted from the mobile phone 11 is sufficiently high, the personal computer 1 displays a clear image of the communication partner on the input display unit 2 and the input level of the radio wave transmitted from the mobile phone 11. Is small, the image of the communication partner to which the mosaic processing is applied is displayed on the input display unit 2. The personal computer 1 changes the mosaic size of the image of the communication partner in accordance with the input level of the radio wave transmitted from the mobile phone 11.
Note that the personal computer 1 may cause the input display unit 2 to change the color of the image of the communication partner in accordance with the radio wave state and display it. For example, when the input level of the radio wave transmitted from the mobile phone 11 is higher, the personal computer 1 causes the input display unit 2 to display a higher-saturation image (so-called vivid image) of the other party of communication. When the input level of the radio wave transmitted from 11 is smaller, an image with lower saturation of the communication partner (so-called faded image) is displayed on the input display unit 2. The personal computer 1 may display the input display unit 2 by changing the color density, hue, or luminance of the image of the communication partner in accordance with the radio wave condition.
Further, the personal computer 1 may display the input display unit 2 by changing the spatial resolution of the image of the communication partner in accordance with the radio wave state. For example, when the input level of the radio wave transmitted from the mobile phone 11 is larger, the personal computer 1 causes the input display unit 2 to display an image of a communication partner that includes more high-frequency components and is transmitted from the mobile phone 11. When the input level of the radio wave is smaller, an image of a communication partner (so-called blurred image) with fewer high-frequency components is displayed on the input display unit 2.
The personal computer 1 causes the input display unit 2 to display an image in which the effects such as the change in transparency, the change in size, or the change in saturation described above are combined in accordance with the radio wave state. It may be.
Further, although the personal computer 1 has been described as displaying an image corresponding to the input level of the radio wave received by the communication unit 28 on the input display unit 2, the image corresponding to the strength of electromagnetic coupling between the reader / writer 33 and the RF tag 212. May be displayed on the input display unit 2.
In the above, the identification number is exchanged by the RF tag and the reader / writer, but it is also possible to exchange the identification number by printing a barcode on each electronic device and reading the barcode. is there.
Further, although Bluetooth has been described as an example of the network, a telephone line, a LAN, a wireless LAN, a WAN, the Internet, or the like can be used.
Furthermore, as the information processing apparatus on which the electronic device is placed, in addition to the input display unit, a palm rest unit, a mouse pad, or a white board of a notebook personal computer can be used.
Further, although the telephone number has been described as an example of the identification number, it may be other than the telephone number as long as it is necessary for accessing the electronic device on the network.
Further, the authentication process of the other party may be performed with the exchange of the identification number.
In the above description, the communication partner terminal by Bluetooth is specified based on the Bluetooth device name or ID stored in the RF tag 212 of the mobile phone 11, but the RF tag 212 is attached to the mobile phone 11. Even if it is not provided, the terminal of the communication partner can be specified by controlling the output power of the radio wave of the communication unit 213 as a wireless module (Bluetooth module).
Hereinafter, a communication system for identifying a communication partner terminal by controlling the output power of a radio wave output from a wireless module will be described.
FIG. 24 is a diagram illustrating a configuration example of a communication system that specifies a communication partner terminal by controlling the output power of radio waves.
In this example, communication between the personal computer 1 and the PDA 501 will be described, but the same applies to the case where the PDA 501 is replaced with the mobile phone 11.
For example, when a communication partner by Bluetooth is specified and communication is established with the partner, the PDA 501 first suppresses the output power of the communication module 511 to the minimum necessary, and the radiated radio wave is, for example, Control to reach only within a few centimeters. As described above, in the state where the minute power mode in which the output power of the radio wave is suppressed is set, the communication module 511 repeatedly performs “Inquiry”, and the range in which the radio wave reaches (for example, a range of several centimeters) Search for a terminal that exists in
When the user places the PDA 501 close to or placed on the personal computer 1 and the radio wave emitted by the communication module 511 is received by the communication unit 28 (wireless module) of the personal computer 1, the communication unit 28 receives the inquiry. As described above, the communication module 511 performs inquiry and page (call) with the communication unit 28 to establish a communication link. The communication link established here is effective within a very narrow range where radio waves reach from the communication module 511 in which the minute power mode is set.
Therefore, the communication module 511 temporarily disconnects the communication link so that communication with the communication unit 28 is possible even if the communication module 511 is separated to some extent, and the power mode setting of the communication module 511 itself is set to a minute power. After changing from the mode to the normal power mode, a communication link is established again with the communication unit 28 based on information already acquired (information acquired by inquiry and page at a short distance).
The re-established communication link is effective in the range where radio waves reach, for example, several tens of meters, as in the case of normal Bluetooth communication, and the distance between the personal computer 1 and the PDA 501 is sufficiently long. However, communication by Bluetooth becomes possible.
As described above, even when the PDA 501 is not provided with the RF tag storing the Bluetooth device name and ID, the user can personalize the PDA 501 by controlling the output power of the communication module. Communication by Bluetooth can be established only by making it close to the computer 1.
When the power mode of the communication module 511 can be switched seamlessly, the power mode setting is changed from the micro power mode to the normal power without temporarily disconnecting the established communication link when the micro power mode is set. You may make it switch to mode.
FIG. 25 is a block diagram showing a configuration example of the PDA 501 in FIG.
The configuration of the PDA 501 is the mobile phone 11 shown in FIG. 6 except that the communication unit 209 (communication module for communication performed via a telephone line), the microphone 210, the speaker 211, and the RF tag 212 are not provided. Since this is basically the same as the configuration of, detailed description of overlapping portions will be omitted as appropriate.
For example, the CPU 521 controls the overall operation of the PDA 501 in accordance with a program expanded from the ROM 522 to the RAM 523, and controls the output power of the radio wave of the communication module 511 according to the communication status as described above.
FIG. 26 is a block diagram illustrating a detailed configuration example of the communication module 511 in FIG.
The communication module 511 is a Bluetooth module, a wireless LAM module, or the like. For example, when the communication module 511 is a Bluetooth module, the configuration includes the configuration of the communication unit 28 shown in FIG. The configuration of the communication module (Bluetooth module) 511 shown in FIG. 26 is shown in a more simplified manner than that shown in FIG. 4 so as to omit redundant description.
When the wireless control unit 541 controls the changeover switch 544 and transmits information from the communication module 511 to an external terminal, the switch 544A is connected to the contact a side, while being transmitted from the external terminal. When receiving incoming information, the switch 544A is connected to the contact b side. In addition, the wireless control unit 541 controls the gain of the power amplifier 545 based on the control from the CPU 521 performed via the bus 524 and the input / output interface 525, and reaches the reach (output power) of the radio wave radiated from the antenna 547. ) To control.
Specifically, when the CPU 521 instructs the wireless control unit 541 to set the micro power mode, the power amplifier 545 is set so that the reach range of the radio wave radiated from the antenna 547 is the minimum necessary. On the other hand, the power amplifier can be specified so that the terminal of the communication partner can be specified, and when it is instructed to switch from the micro power mode to the normal power mode, the reach of the output radio wave becomes wider The gain of 545 is controlled.
The baseband control unit 542 controls the baseband signal of the transmission / reception signal, similarly to the baseband control unit 127 of FIG. The modulation / demodulation processing unit 543 performs GFSK modulation processing, spread spectrum processing based on the hopping frequency, and the like on the output from the baseband control unit 542, and outputs the obtained signal from the antenna 547 via the power amplifier 545. Also, the modulation / demodulation processing unit 543 performs spectrum despreading processing and GFSK demodulation processing on the output from the LNA (Low Noise Amplifier), and outputs the obtained signal to the baseband control unit 542.
The configuration of the personal computer 1 is the same as the configuration shown in FIG. In the communication system shown in FIG. 24, the personal computer 1 does not need to be provided with the reader / writer 33 shown in FIG.
Next, the operation of the communication system of FIG. 24 will be described with reference to the flowchart of FIG. In this example, a case where a communication partner by Bluetooth is specified and communication is established will be described.
For example, when the user instructs to perform Bluetooth communication, the communication module 511 is activated based on the control from the CPU 521, and sets the micro power mode as its own power mode in step S201. In addition, the communication module 511 proceeds to step S202, repeatedly executes Inquiry, and searches for a nearby terminal. In the inquiry executed in step S202, the minute power mode is set and the radio wave reach is suppressed to the necessary minimum. For example, an IQ packet (Inquiry packet) is within a range of several centimeters from the antenna 547. ) Is broadcast repeatedly.
On the other hand, in step S211, the communication unit 28 of the personal computer 1 is in a state of repeatedly executing the inquiry scan and page scan, and waits until there is a request for inquiry and page from another terminal.
When the user brings the PDA 501 close to the personal computer 1 and the communication unit 28 of the personal computer 1 is within the reach of the radio wave from the communication module 511 of the PDA 501, the IQ packet broadcast from the communication module 511 is transmitted in step S 222. Received by the communication unit 28.
When the IQ packet broadcast from the communication module 511 is received, the communication unit 28 proceeds to step S223 to respond to the IQ packet, and transmits the FHS packet to the communication module 511. The FHS packet includes information indicating the Bluetooth address and Bluetooth clock of the personal computer 1 as attribute information of the personal computer 1 (Bluetooth slave).
When the FHS packet transmitted from the communication unit 28 is received in step S203, the process proceeds to step S204, and the communication module 511 requests the communication unit 28 to connect.
That is, when an ID packet is transmitted from the communication module 511 to the communication unit 28 and the same ID packet as the ID packet is sent back from the communication unit 28 to the communication module 511, the Bluetooth address of the communication module 511 and An FHS packet including a Bluetooth clock is transmitted from the communication module 511 to the communication unit 28.
When the FHS packet transmitted from the communication module 511 is received by the communication unit 28 in step S224, synchronization of the frequency axis (frequency hopping pattern) and time axis (time slot) is established between the communication module 511 and the communication unit 28. Then, the data link (communication link) is established (state 1).
For example, when a Bluetooth data link is established for the first time between the communication unit 28 and the communication module 511, the communication module 511 transmits a PIN (Personal Identification Number) code to the communication unit 28 in step S205. , Mutually authenticate. The PIN code transmitted from the communication module 511 is received by the communication unit 28 in step S225, and then various link keys are exchanged between the communication module and the communication unit 28 based on the PIN code and random numbers. Is set. The PIN code may be transmitted / received after being encrypted with the public key provided from the communication unit 28 to the communication module 511. That is, in this case, the communication unit 28 manages the secret key corresponding to the public key provided to the communication module 511 by itself. Thereby, security can be improved, and communication by Bluetooth can be executed only between the personal computer 1 and the PDA 501 more reliably.
The communication link established as described above is effective within a range of several centimeters from which the radio wave from the communication module 511 in which the micro power mode is set can be reached. Therefore, the communication module 511 is separated to some extent. Even in such a case, in order to switch the power mode so that communication with the communication unit 28 is possible, the communication unit 28 is requested to temporarily disconnect the data link in step S206. At this time, the information acquired by the processing so far, such as the Bluetooth address and PIN code of the communication unit 28, is stored in the communication module 511.
The communication unit 28 that has received the request in step S226 saves the information such as the Bluetooth address and PIN code of the communication module 511 acquired so far, and disconnects the data link, similarly to the communication module 511 (state 2). .
In step S207, the communication module 511 sets the power mode for controlling the output power to the normal power mode based on the control from the CPU 521 to establish the data link with the communication unit 28 again. Thereby, for example, Bluetooth radio waves from the communication module 511 reach a range of several tens of meters.
In step S208, the communication module 511 identifies the personal computer 1 as a communication partner terminal based on the information stored immediately before disconnecting the data link, and requests the communication unit 28 to establish a connection. .
When this request is received by the communication unit 28 in step S227 and setting is performed in each terminal, a state where the data link is established between the communication module 511 and the communication unit 28, that is, the normal power mode is set. The radio wave from the communication module 511 arrives, and for example, Bluetooth communication is possible within a range of several tens of meters (state 3).
As described above, the communication system shown in FIG. 24 that identifies the adjacent terminal as the communication partner terminal is applied to the information processing system including the personal computer 1 and the mobile phone 11 shown in FIG. It is possible to realize an information processing system in which an image representing an adjacent terminal is displayed on the LCD 32 of the personal computer 1 according to the distance. That is, the user can know the communication distance that can be actually connected, and can reliably perform communication between terminals.
The series of processes described above can be executed by software. In this case, a program constituting the software can execute various functions by installing a computer incorporated in dedicated hardware or various programs, for example, a general-purpose It is installed on a personal computer or the like from a network or a recording medium.
As shown in FIG. 2, the recording medium is distributed to provide a program to the user separately from the apparatus main body, and includes a magnetic disk 41 (including a floppy (registered trademark) disk) on which the program is recorded. Optical disc 42 (including CD-ROM (Compact Disc-Read Only Memory), DVD (Digital Versatile Disc)), magneto-optical disc 43 (including MD (Mini-Disc) (trademark)), or semiconductor memory 44 In addition to being configured by package media, it is configured by a ROM 22 in which a program is recorded and a hard disk included in the storage unit 26 provided to the user in a state of being preinstalled in the apparatus main body.
In the present specification, the step of describing the program recorded on the recording medium is not limited to the processing performed in chronological order according to the described order, but is not necessarily performed in chronological order. It also includes processes that are executed individually.
Further, in this specification, the system represents the entire apparatus constituted by a plurality of apparatuses.
Industrial applicability
As described above, according to the present invention, display of an image corresponding to an electronic device is controlled based on the input level of the radio wave transmitted from the electronic device and communicated with the electronic device via the radio wave. Therefore, it becomes possible to know the communication distance that can be actually connected, and thus it is possible to reliably exchange information between the information processing apparatus and the electronic device.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration example of an information processing system to which the present invention is applied.
FIG. 2 is a block diagram illustrating a configuration example of the personal computer of FIG.
FIG. 3 is a block diagram showing the configuration of the reader / writer 33.
FIG. 4 is a block diagram illustrating a configuration of the communication unit 28.
FIG. 5 is a block diagram illustrating a configuration of a program executed by the personal computer 1.
FIG. 6 is a block diagram showing the configuration of the mobile phone 11.
FIG. 7 is a block diagram showing the configuration of the RF tag 212.
FIG. 8 is a diagram illustrating an example of functional blocks of the mobile phone 11.
FIG. 9 is a flowchart for explaining processing of the personal computer in the information processing system of FIG.
FIG. 10 is a flowchart for explaining processing of the mobile phone in the information processing system of FIG.
FIG. 11 illustrates the processing of the personal computer in the information processing system of FIG.
FIG. 12 is a flowchart for explaining processing of the mobile phone in the information processing system of FIG.
FIG. 13 is a diagram for explaining exchange of data between the mobile phone and the personal computer.
FIG. 14 is a flowchart for explaining processing of the mobile phone in the example of FIG.
FIG. 15 is a flowchart for explaining processing of the personal computer in the example of FIG.
FIG. 16 is a diagram illustrating an example of a display indicating a communication state.
FIG. 17 is a diagram illustrating an example of a display indicating a communication state.
FIG. 18 is a diagram for explaining an example of a display indicating a communication state.
FIG. 19 is a flowchart for explaining processing for displaying a radio wave state.
FIG. 20 is a diagram for explaining an example of a display indicating a communication state.
FIG. 21 is a diagram illustrating an example of a display indicating a communication state.
FIG. 22 is a diagram illustrating an example of a display indicating a communication state.
FIG. 23 is a flowchart for explaining processing for displaying a radio wave state.
FIG. 24 is a diagram showing a configuration example of a communication system to which the present invention is applied.
FIG. 25 is a block diagram showing a configuration example of the PDA of FIG.
FIG. 26 is a block diagram illustrating a configuration example of the wireless module in FIG.
FIG. 27 is a flowchart for explaining the operation of the communication system of FIG.

Claims (10)

Communication means for communicating with electronic devices via radio waves;
Obtaining means for obtaining identification information of the electronic device;
Based on the input level of the radio wave transmitted from the electronic device existing within the communication range of communication performed by the communication unit, specified by the identification information acquired by the acquisition unit among a plurality of electronic devices An information processing apparatus comprising: display control means for controlling display of an image of the shape of the electronic device. The acquisition means is a communication method for transmitting and receiving information via electromagnetic waves, or a communication method of Bluetooth that specifies a communication partner by searching for devices in the weak power mode. Get
The information processing apparatus according to claim 1, wherein the communication unit communicates with the electronic device based on the identification information. The information processing apparatus according to claim 1, wherein the display control unit controls display so that the image is displayed with transparency corresponding to an input level of the radio wave. The information processing apparatus according to claim 1, wherein the display control unit controls display so that the image is displayed at a position corresponding to the input level of the radio wave. The information processing apparatus according to claim 1, wherein the display control unit controls display so that the image having a size corresponding to the input level of the radio wave is displayed. The information processing apparatus according to claim 1, wherein the display control unit controls display so as to display the image having a resolution corresponding to the input level of the radio wave. The information processing apparatus according to claim 1, wherein the display control unit controls display so that the image is displayed in a color corresponding to an input level of the radio wave. The information processing apparatus according to claim 1, wherein the display control unit controls display so as to display the image to which mosaic processing corresponding to the input level of the radio wave is applied. A communication processing step for communicating with an electronic device via radio waves;
An acquisition processing step of acquiring identification information of the electronic device;
Based on the input level of the radio wave transmitted from the electronic device existing within the communication range of the communication performed by the processing of the communication processing step, acquired by the processing of the acquisition processing step among a plurality of electronic devices. And a display control processing step for controlling display of an image of the shape of the electronic device specified by the identification information. A communication processing step for communicating with an electronic device via radio waves;
An acquisition processing step of acquiring identification information of the electronic device;
Based on the input level of the radio wave transmitted from the electronic device existing within the communication range of the communication performed by the processing of the communication processing step, acquired by the processing of the acquisition processing step among a plurality of electronic devices. And a display control processing step for controlling display of an image of the shape of the electronic device specified by the identification information. A recording medium on which a computer-readable program is recorded.

Images